Doping Engineering in Manganese Oxides for Aqueous Zinc-Ion Batteries

Manganese oxides (MnxOy) are considered a promising cathode material for aqueous zinc-ion batteries (AZIBs) due to their high theoretical specific capacity, various oxidation states and crystal phases, and environmental friendliness. Nevertheless, their practical application is limited by their intrinsic poor conductivity, structural deterioration, and manganese dissolution resulting from Jahn–Teller distortion. To address these problems, doping engineering is thought to be a favorable modification strategy to optimize the structure, chemistry, and composition of the material and boost the electrochemical performance. In this review, the latest progress on doped MnxOy-based cathodes for AZIBs has been systematically summarized. The contents of this review are as follows: (1) the classification of MnxOy-based cathodes; (2) the energy storage mechanisms of MnxOy-based cathodes; (3) the synthesis route and role of doping engineering in MnxOy-based cathodes; and (4) the doped MnxOy-based cathodes for AZIBs. Finally, the development trends of MnxOy-based cathodes and AZIBs are described.


Introduction
The exhaustive use of traditional energy sources, such as coal and fossil fuels, has not only depleted traditional energy reserves but also caused significant environmental pollution.Therefore, there is an imperative requirement to develop clean and renewable energy resources, including solar energy, wind energy, ocean energy, and biomass energy.However, these new energy sources have time and space discontinuity, which limits their widespread application.Therefore, efficient energy conversion and storage systems are required [1][2][3][4].Rechargeable batteries are considered as the most promising candidates due to their excellent energy efficiency, long cycle life, cost-effectiveness, and environmental friendliness [5][6][7][8].So far, rechargeable batteries utilizing various charge carriers, such as Li + , Na + , K + , Ca 2+ , Mg 2+ , Zn 2+ , and Al 3+ , accompanied by either organic or aqueous electrolyte have been reported [9][10][11].Although a high energy density results from the wide electrochemical window in the organic electrolyte, the toxicity, flammability, and volatility, which pose serious safety hazard and environmental risks, limit the practical application of non-aqueous batteries [12].In contrast, aqueous batteries using water as the electrolyte offer several advantages, consisting of simple assembly process, extended service life, enhanced safety, environmental friendliness, and affordability.Importantly, the higher ionic conductivity of the aqueous electrolyte than that of the organic electrolyte can grant aqueous batteries a superior rate performance and fast charging characteristics [13][14][15].
Among these ion batteries, AZIBs have several advantages: (i) high ionic conductivity in aqueous electrolyte [16]; (ii) reversible electrodeposition of the zinc anode [17]; (iii) low redox potential (−0.76 V vs. SHE); (iv) high gravimetric capacity (820 mAh g −1 ) and volume specific capacity (5851 mAh cm −3 ) [18]; (v) excellent stability of the zinc anode in neutral solution [17]; (vi) non-volatile and non-toxic aqueous electrolyte [19]; and (vii) abundant zinc resources contributing to a low cost [20].Nevertheless, the commercial application of AZIBs is hampered by the scarcity of substances capable of reversible Zn 2+ storage upon extended cycling, as well as the structural collapse of cathodes.As the primary host for the insertion and extraction of Zn 2+ , cathode materials are a crucial factor in influencing the electrochemical performance of AZIBs [21].To address these challenges, extensive research efforts have been devoted to developing high-electrochemical-performance cathode materials for AZIBs.
Currently, cathode materials in AZIBs can be divided into five categories: manganesebased compounds [22], vanadium-based oxides and vanadates [23], Prussian blue analogues [24], organic compounds [25], and metal chalcogenides [26].Vanadium-based materials are prone to collapse after long-term cycling.Otherwise, they have a number of problems to be solved, including potential toxicity, slow kinetics for Zn 2+ insertion, and a low operating voltage.Prussian blue analogues with inherently low specific capacity tend to be easily oxidized under high potentials, resulting in rapid specific capacity degradation during cycling.In general, organic compounds have poor crystallinity or amorphous structure, an unsatisfactory output voltage, and a poor rate performance and cycling stability.Transition metal sulfides are affected by problems such as serious volume expansion, poor conductivity, and low discharge voltage, which hinder their practical application.Among them, manganese-based compounds have diverse valence states and crystal phases, and a series of redox reactions during charging/discharging cycles provide optional capacities and voltage platforms [27][28][29].In addition, manganese-based compounds possess a stable tunneling structure and a three-dimensional spatial framework, facilitating the sufficient accommodation of Zn 2+ [30][31][32] and ensuring the acceptable operating voltage and high theoretical capacity of batteries.Thus, in the past few years, manganese-based materials have been widely utilized as cathodes for AZIBs and have become a research hotspot [33,34].However, manganese-based materials have several drawbacks to overcome, including Mn 3+ displacement and Mn dissolution induced by the Jahn-Teller effect, structural changes inducing capacity decay and cycle life reduction, and low ionic conductivity inducing poor rate performance and unsatisfactory capacity [35][36][37].Therefore, it is imperative to propose solutions to improve the electrochemical performance of Mn x O y cathodes and promote their practical application in AZIBs.
Given the shortcomings of Mn x O y cathodes, various strategies have been exploited to improve their electrochemical performance, including defect engineering, doping engineering, interface engineering, pre-intercalation engineering, and morphology controlling.Compared to other modification strategies, doping engineering can improve the electrochemical performance of AZIBs by boosting electron and ion conductivity, expanding the availability of electrochemical active sites, accelerating the reaction kinetics, and ensuring the longevity of the structural integrity [36,37].As a common and widely used modification strategy, doping engineering involving cation doping and anion doping has attracted extensive research interest.Doping engineering is utilized to alter the electrical, magnetic, optical, mechanical, and thermal properties of materials by manipulating their charge and spin distribution and band gap [37][38][39].For Mn x O y cathodes, doping engineering can modulate their intrinsic crystal structure, charge and ion state, and band gap and further influence their electrochemical performance [38,39].In particular, the Zn 2+ storage performance of Mn x O y is closely related to the composition, doping level and position, and bonding configuration of the dopants.Over the past few decades, great progress has been made in doped Mn x O y -based cathodes, and numerous synthesis routes have been developed.However, most of the currently reported methods are complex and expensive for grid-scale production; a feasible and inexpensive method needs to be further explored before the commercialization of AZIBs.
In recent years, numerous reviews have examined Mn x O y -based cathodes for AZ-IBs, including MnO 2 -based cathodes [38][39][40][41][42] and the crystal structure, energy storage mechanisms, and modification strategies of Mn x O y -based cathodes [43][44][45][46][47][48][49].However, a comprehensive and systematic summary of the beneficial effects of doping on the elec-trochemical performance of Mn x O y -based cathodes for AZIBs is still needed.In addition, a systematic categorization and in-depth analysis concerning the energy storage mechanisms within doping-enhanced Mn x O y -based cathodes for AZIBs is still lacking.Based on the different oxidation states and crystal structures, this review first focuses on the classification of Mn x O y -based cathodes.Then, the charge storage mechanisms, the existing problems, and the corresponding optimization strategies for Mn x O y cathodes are discussed in detail.In addition, according to different compositions (MnO, MnO 2 , Mn 2 O 3 , and Mn 3 O 4 ) and crystal phases (α-, δ-, β-, ε-, and γ-MnO 2 ), the doping technology, electrochemical performance, and inherent improvement mechanisms of doped Mn x O y cathodes are comprehensively and incisively elaborated.Finally, valuable research directions for Mn x O y cathodes and AZIBs are prospected.

Classification of Mn x O y -Based Cathodes
As shown in Figure 1, there are many forms of Mn x O y , including MnO 2 , MnO, Mn 2 O 3 , and Mn 3 O 4 , in which MnO 2 consists of several crystal structures, containing α-, β-, γ-, δ-, ε-, λ-, T-(perovskite MnO 2 ), and R-MnO 2 .The octahedral MnO 6 unit is the basic building block for all MnO 2 crystal forms.Due to the advantages of various Mn x O y structures, it has been widely investigated as a promising cathode in AZIBs in recent years.As an optimization strategy, doping engineering can tailor the electrical, magnetic, optical, mechanical, and thermal properties of Mn x O y by manipulating their charge and spin distribution and band gap, thus boosting the electrochemical performance.Previous works have confirmed that the electrochemical performance of Mn x O y (e.g., MnO, MnO 2 , Mn 2 O 3 , and Mn 3 O 4 ) can be improved after cation or/and anion doping due to their effect on the average valence, crystalline phase, and structure [50][51][52][53][54].In this section, different phases and structures of Mn x O y are summarized, which can help to understand the mechanism after ion doping.
Materials 2024, 17, x FOR PEER REVIEW 3 of 33 comprehensive and systematic summary of the beneficial effects of doping on the electrochemical performance of MnxOy-based cathodes for AZIBs is still needed.In addition, a systematic categorization and in-depth analysis concerning the energy storage mechanisms within doping-enhanced MnxOy-based cathodes for AZIBs is still lacking.Based on the different oxidation states and crystal structures, this review first focuses on the classification of MnxOy-based cathodes.Then, the charge storage mechanisms, the existing problems, and the corresponding optimization strategies for MnxOy cathodes are discussed in detail.In addition, according to different compositions (MnO, MnO2, Mn2O3, and Mn3O4) and crystal phases (α-, δ-, β-, ε-, and γ-MnO2), the doping technology, electrochemical performance, and inherent improvement mechanisms of doped MnxOy cathodes are comprehensively and incisively elaborated.Finally, valuable research directions for MnxOy cathodes and AZIBs are prospected.

Classification of MnxOy-Based Cathodes
As shown in Figure 1, there are many forms of MnxOy, including MnO2, MnO, Mn2O3, and Mn3O4, in which MnO2 consists of several crystal structures, containing α-, β-, γ-, δ-, ε-, λ-, T-(perovskite MnO2), and R-MnO2.The octahedral MnO6 unit is the basic building block for all MnO2 crystal forms.Due to the advantages of various MnxOy structures, it has been widely investigated as a promising cathode in AZIBs in recent years.As an optimization strategy, doping engineering can tailor the electrical, magnetic, optical, mechanical, and thermal properties of MnxOy by manipulating their charge and spin distribution and band gap, thus boosting the electrochemical performance.Previous works have confirmed that the electrochemical performance of MnxOy (e.g., MnO, MnO2, Mn2O3, and Mn3O4) can be improved after cation or/and anion doping due to their effect on the average valence, crystalline phase, and structure [50][51][52][53][54].In this section, different phases and structures of MnxOy are summarized, which can help to understand the mechanism after ion doping.

α-MnO 2
α-MnO 2 has a one-dimensional [2 × 2, ~0.46 nm × 0.46 nm] tunnel structure, which belongs to the body-centered tetragonal crystal system and the I4/m space group.The large pore size of α-MnO 2 enhances the diffusion performance of Zn 2+ ions within the matrix framework.This allows for effective storage and the rapid transfer of guest cations following the z-axis direction [37,40,49].

δ-MnO 2
δ-MnO 2 is composed of corner-sharing MnO 6 octahedra and corresponds to the monoclinic crystal phase with the P2/m space group.Additionally, it exhibits a representative two-dimensional laminar structure characterized by a substantial inter-lamellar spacing of approximately 7 Å; this feature allows for an increased number of active sites that facilitate the intercalation and de-intercalation of Zn 2+ .The layered structure of δ-MnO 2 is constructed from MnO 6 octahedral sheets that grow along shared edges.To enhance the stability of this layered architecture, interlayer spaces are occupied by water molecules and cations [40].

ε-MnO 2
ε-MnO 2 , similar to γ-MnO 2 , is also referred to as hexagonal pyrolusite.Its manganese lattice is highly disordered, and the tunnels within its structure are irregularly shaped.In addition, ε-MnO 2 has a metastable phase containing edge-shared MnO 6 octahedra, where Y represents vacancies.This arrangement hinders the rapid intercalation and deintercalation of ions and protons, which is essential for efficient energy storage.The inherent low electrochemical activity, coupled with poor conductivity, yields suboptimal electrochemical characteristics.

MnO
MnO consists of a MnO 6 octahedron and lacks a tunnel structure, making it electrochemically inactive.However, the addition of Mn defects is able to create pathways for the insertion of Zn 2+ , thereby enhancing the conductivity of MnO [40].

Mn 2 O 3
The crystal structure of Mn 2 O 3 is devoid of both tunnel structures and expansive interlayer spacing.Mn 3+ is situated in the octahedral coordination, with four Mn ions encircling each oxygen ion.Furthermore, a reversible phase transition reaction takes place between Mn 2 O 3 and birnessite during the cycling.

Mn 3 O 4
Mn 3 O 4 is a multivalent manganese oxide featuring a spinel structure, with the chemical formula Mn II Mn III 2 O 4 .It incorporates both Mn 2+ and Mn 3+ valence states.Mn 2+ is located in the tetrahedral (4a) sites, while the Mn 3+ occupies the octahedral (8d) sites within an intermediate, slightly twisted cubic close-stacked array of oxygen atoms [43].Moreover, Mn 3 O 4 is also recognized as an outstanding cathode material due to its excellent theoretical capacity.

Energy Storage Mechanisms of Mn x O y -Based AZIBs
The in-depth study of the energy storage mechanisms can effectively guide the optimization of materials' performance, making it a core focus in the field of energy storage materials.However, due to the diverse crystal structure of Mn x O y and the influence of the electrolyte, the current charge storage mechanisms of AZIBs are full of controversies, and there is no generally accepted theory.Based on the latest reported works, there are four types of reaction mechanisms (Figure 2), including Zn 2+ intercalation/de-intercalation, reversible Zn 2+ and H + co-intercalation/de-intercalation, the chemical conversion reaction, and dissolution/deposition.

Mn3O4
Mn3O4 is a multivalent manganese oxide featuring a spinel structure, with the chemical formula Mn II Mn III 2O4.It incorporates both Mn 2+ and Mn 3+ valence states.Mn 2+ is located in the tetrahedral (4a) sites, while the Mn 3+ occupies the octahedral (8d) sites within an intermediate, slightly twisted cubic close-stacked array of oxygen atoms [43].Moreover, Mn3O4 is also recognized as an outstanding cathode material due to its excellent theoretical capacity.

Energy Storage Mechanisms of MnxOy-Based AZIBs
The in-depth study of the energy storage mechanisms can effectively guide the optimization of materials' performance, making it a core focus in the field of energy storage materials.However, due to the diverse crystal structure of MnxOy and the influence of the electrolyte, the current charge storage mechanisms of AZIBs are full of controversies, and there is no generally accepted theory.Based on the latest reported works, there are four types of reaction mechanisms (Figure 2), including Zn 2+ intercalation/de-intercalation, reversible Zn 2+ and H + co-intercalation/de-intercalation, the chemical conversion reaction, and dissolution/deposition.

Zn 2+ Insertion Mechanism
The Zn 2+ insertion mechanism belongs to the earliest and most important mechanism in AZIBs.Like the insertion mechanism existing in traditional alkali-metal-ion batteries, Zn 2+ can be easily inserted/extracted from manganese-based materials during the charging/discharging process (Figure 2a).However, due to the different crystal phases of manganese-based materials, the Zn 2+ insertion mechanism often manifests in a more complex reaction pathway [55].For example, in the case of MnxOy with different crystal phases, although they will gradually evolve into a MnxOy-layered phase with interlayer water molecules on account of structural transformation during the redox reaction, the evolution process is partially different [56].For example, in the case of α-MnO2 with 1 × 1 or 2 × 2 tunnel structures, Kang's group [57] observed a structural evolution process where Mn 4+ is reduced to Mn 3+ .Then, the Mn 3+ is dissolved into the electrolyte through chemical disproportionation, and finally, the Zn-Bussel mine is obtained.For γ-MnO2 with alternating pyrolusite and rhodochrosite channels, various intermediates including ZnMn2O4, tunnel γ-ZnxMnO2, and layered ZnyMnO2 may appear successively during its evolution [58].

Zn 2+ Insertion Mechanism
The Zn 2+ insertion mechanism belongs to the earliest and most important mechanism in AZIBs.Like the insertion mechanism existing in traditional alkali-metal-ion batteries, Zn 2+ can be easily inserted/extracted from manganese-based materials during the charging/discharging process (Figure 2a).However, due to the different crystal phases of manganese-based materials, the Zn 2+ insertion mechanism often manifests in a more complex reaction pathway [55].For example, in the case of Mn x O y with different crystal phases, although they will gradually evolve into a Mn x O y -layered phase with interlayer water molecules on account of structural transformation during the redox reaction, the evolution process is partially different [56].For example, in the case of α-MnO 2 with 1 × 1 or 2 × 2 tunnel structures, Kang's group [57] observed a structural evolution process where Mn 4+ is reduced to Mn 3+ .Then, the Mn 3+ is dissolved into the electrolyte through chemical disproportionation, and finally, the Zn-Bussel mine is obtained.For γ-MnO 2 with alternating pyrolusite and rhodochrosite channels, various intermediates including ZnMn 2 O 4 , tunnel γ-Zn x MnO 2 , and layered Zn y MnO 2 may appear successively during its evolution [58].

Zn 2+ /H + Co-Insertion Mechanism
The co-intercalation/de-intercalation mechanism of Zn 2+ and H + involves the transport of two charge carriers into the skeleton of the manganese-based material, which differs significantly from the Zn 2+ insertion mechanism (Figure 2b).Due to the smaller size and weaker electrostatic interaction of H + compared to Zn 2+ , the insertion thermodynamics and kinetics of the two charge carriers are completely different [33,59,60].It is generally believed that the interaction between Zn 2+ and MnO 2 occurs through the intercalation process, while the interaction between H + and MnO 2 occurs through the chemical conversion reaction [37,[61][62][63].During the discharge process, H + and Zn 2+ are incorporated into the manganese-based material to form MnOOH and Zn x MnO 2 , respectively, and then released during the subsequent charging process, which together form a reversible electrochemical process.However, due to the different reaction kinetics, researchers have different opinions on the order of H + and Zn 2+ intercalation reactions [37,64,65].Many scholars have conducted related research using different MnO 2 materials and provided various evidence regarding the controversy over the insertion sequence, but no unified conclusion has been reached yet.

Conversion Reaction Mechanism
The chemical conversion reaction mechanism is distinct from the insertion mechanism of Zn 2+ , in which the insertion/extraction of Zn 2+ cannot contribute to the battery capacity (Figure 2c) [66][67][68][69].Oh et al. [70] proposed that during the discharge process, the Mn element in MnO 2 is first electrochemically reduced to Mn 3+ and then dissolved in the electrolyte as Mn 2+ through a disproportionation reaction.Therefore, the generation of Zn 4 SO 4 (OH) 6 •5H 2 O and the reduction-disproportionation-dissolution of Mn mainly contribute to its capacity.However, more scholars believe that the chemical conversion mechanism refers to the reversible electrochemical reaction between MnO 2 and MnOOH/Zn 4 SO 4 (OH)   [70,72].Given the scarcity and controversy of reports on the chemical conversion mechanism, most work focuses on the embedding mechanism of Zn 2+ as the electrochemical reaction mechanism.

Dissolution/Deposition Mechanism
The dissolution/deposition mechanism exhibits a significant correlation with the composition of the electrolyte.In short, layered MnO 2 and Mn 2+ undergo a reversible dissolution/deposition process during charging/discharging (Figure 2d).Different from the mechanism that is mainly based on a single-electron redox reaction, the dissolution/deposition mechanism represents a new redox chemistry that relies on a two-electron transfer reaction, which is a crucial factor for improving the battery capacity [27,73,74].Kundu et al. [75] carried out extensive research on the electrolyte of α-MnO 2 and found that when the electrolyte does not contain additives that can form a layered hydroxide (Zn 4 SO 4 (OH) 6 •5H 2 O), the capacity of the battery will be significantly attenuated.Similarly, Jaekook Kim et al. [76] found that when the electrolyte contains both ZnSO 4 and MnSO 4 as additives, it is beneficial for the reversible electrodeposition/dissolution of Mn 2+ on the surface of the cathode and formation of the surface MnO 2 layer or bulk phase formed by reversible Zn 2+ insertion, leading to excellent structural stability and high reversibility.Liang et al. [77] conducted a capacity test in single ZnSO 4 electrolyte and found that its discharge capacity was significantly attenuated, speculating that the dissolution/deposition mechanism controls the energy storage process.

Synthesis Route of Heteroatom-Doped Mn x O y -Based Cathodes
An essential step in optimizing the electrochemical performance of doped manganese oxides is the synthesis process of doped manganese oxides.The methods for synthesizing doped manganese oxides are diverse, and the following section presents several widely used approaches.

Hydrothermal Method
The hydrothermal method is the most commonly used method due to its ease of control, allowing for the production of nanoparticles with tailored morphologies, easy control of ion doping, and the synthesis of a wide range of phase structures.In a study by Li et al. [78], stannous chloride (SnCl 2 ) was utilized as the dopant, with potassium permanganate (KMnO 4 ) and manganese sulfate monohydrate (Mn(SO 4 )•H 2 O) serving as the manganese sources.The pH of the solution was meticulously adjusted with hydrochloric acid.Subsequent hydrothermal processing at 180 • C for 24 h yielded a uniform rod-like structure of α-MnO 2 .Yan et al. [79] employed aluminum nitrate (Al(NO 3 ) 3 ) as a heteroatom dopant.The black aluminum was pre-embedded into the MnO 2 matrix through a one-step hydrothermal process, which involved a continuous reaction at 140 • C for 4 h.The resulting material not only exhibits superior zinc storage performance but also displays a distinctive morphological structure.It is characterized by a 3D sea-urchin-like hollow microsphere with a size of 4.5 to 5.0 µm.Li et al. [80] reported an innovative strategy for the preparation of V-doped MnO 2 using a hydrothermal method with an excess of dopant.As depicted in Figure 3a, a VMO/V 2 O 5 hydrogel monolithic column containing V 2 O 5 precipitates was produced by reacting a mixture of ammonium metavanadate (NH 4 VO 3 ) and manganese salt in an autoclave for 12 h.After thorough washing with copious amounts of deionized water and the subsequent dissolution of the V 2 O 5 , the final product was V-doped MnO 2 .Though the hydrothermal method has many advantages, commercialization is still limited by the high energy demands, high equipment requirements, and long reaction times, which increase the product costs.

Synthesis Route of Heteroatom-Doped MnxOy-Based Cathodes
An essential step in optimizing the electrochemical performance of doped manganese oxides is the synthesis process of doped manganese oxides.The methods for synthesizing doped manganese oxides are diverse, and the following section presents several widely used approaches.

Hydrothermal Method
The hydrothermal method is the most commonly used method due to its ease of control, allowing for the production of nanoparticles with tailored morphologies, easy control of ion doping, and the synthesis of a wide range of phase structures.In a study by Li et al. [78], stannous chloride (SnCl2) was utilized as the dopant, with potassium permanganate (KMnO4) and manganese sulfate monohydrate (Mn(SO4)•H2O) serving as the manganese sources.The pH of the solution was meticulously adjusted with hydrochloric acid.Subsequent hydrothermal processing at 180 °C for 24 h yielded a uniform rod-like structure of α-MnO2.Yan et al. [79] employed aluminum nitrate (Al(NO3)3) as a heteroatom dopant.The black aluminum was pre-embedded into the MnO2 matrix through a one-step hydrothermal process, which involved a continuous reaction at 140 °C for 4 h.The resulting material not only exhibits superior zinc storage performance but also displays a distinctive morphological structure.It is characterized by a 3D sea-urchin-like hollow microsphere with a size of 4.5 to 5.0 µm.Li et al. [80] reported an innovative strategy for the preparation of V-doped MnO2 using a hydrothermal method with an excess of dopant.As depicted in Figure 3a, a VMO/V2O5 hydrogel monolithic column containing V2O5 precipitates was produced by reacting a mixture of ammonium metavanadate (NH4VO3) and manganese salt in an autoclave for 12 h.After thorough washing with copious amounts of deionized water and the subsequent dissolution of the V2O5, the final product was Vdoped MnO2.Though the hydrothermal method has many advantages, commercialization is still limited by the high energy demands, high equipment requirements, and long reaction times, which increase the product costs.

Co-Precipitation Method
Co-precipitation is widely used due to its significant advantages: the resulting products exhibit uniform mixing and a short synthesis time and their morphology, particle size, and properties can be finely tuned by changing the precipitation parameters.Lu and colleagues [81] employed the co-precipitation method to prepare a La-Ca co-doped ε-MnO 2 cathode (LCMO).The urchin-like nanostructure provides numerous active sites for Zn 2+ .The dual-ion doping strategy enlarges the tunnel diameter of MnO 2 , effectively lowering the energy barrier for Zn 2+ diffusion.In addition, the LCMO exhibits enhanced conductivity and a more stable crystalline structure, which significantly boosts its electrochemical performance.Dong and team [82] synthesized an aerogel-structured MnO 2 composed of defective ultrathin nanosheets using a simple co-precipitation method augmented with V 2 O 5 gel.Vanadium doping facilitated the creation of abundant oxygen vacancies and the assembly of an aerogel morphology from ultrathin nanosheets.The presence of V doping and oxygen vacancies can modulate the electronic structure, thereby enhancing the conductivity and lowering the Zn 2+ diffusion energy barrier, which in turn improves the electrochemical performance.Although the co-precipitation method offers considerable advantages and has some industrial applications, it still had some drawbacks that needed to be overcome, including the presence of pH gradients resulting from the ineffective stirring, the broad particle size distribution of the products, and extra complex high-temperature treatment to eliminate the impurities.

Ball Milling
The synthesis of doped manganese oxide through ball milling involves the thorough mixing of manganese oxide with the dopant, followed by the introduction of the mixture into a ball mill.The addition of an appropriate amount of grinding media facilitates the milling process, ultimately yielding the desired doped manganese oxide.This method is favored for its simplicity, ease of operation, cost effectiveness, and the uniformity of raw material mixing.For example, Sun et al. [83] discovered that simple wet ball milling could incorporate nitrogen atoms into MnO 2 for the first time.Using MnO 2 powder, urea particles, and deionized water as precursors, samples with and without urea particles were prepared to investigate the effect of nitrogen doping.It was concluded that interstitial nitrogen-doped MnO 2 , in conjunction with oxygen vacancies, exhibits an increased adsorption capacity for H + , which in turn affects the electrochemical performance of the cathode.However, the milling easily introduces impurities during the milling process, and excessive milling can lead to lattice distortion or amorphization, which adversely affects the performance of the material.

Calcination Treatment
The calcination treatment is simple and easy to scale up, which can provide high kinetics for guest ion intercalation and make it accessible for various applications.Xia et al. [84] reported an N-doped MnO 2−x dendritic structure cathode by calcining MnO 2 in an NH 3 atmosphere at a low temperature of 200 • C. As depicted in Figure 3c, MnO 2 nanosheets were initially deposited on a TiC/C framework using a hydrothermal approach.The resulting MnO 2 @TiC/C was then annealed in an NH 3 atmosphere.Similarly, Sun et al. [35] prepared an S-doped MnO 2 by calcining MnO 2 under S vapor at the temperature of 450 • C. The S doping can moderate the electronic conductivity, reduce the electronegativity of MnO 2 , and debilitate the electrostatic interactions with Zn 2+ , thus boosting the electrochemical performance.However, due to the surface reaction, the doping usually occurs near the surface of MnO 2 , which can hardly be homogeneously doped at the atomic level, and the doping content cannot be precisely controlled.Thus, the calcination treatment is usually combined with the hydrothermal method, co-precipitation method, and sol-gel method as a post-treatment.In other words, precursors are first synthesized and then calcined to form final products.

Sol-Gel Process
Different from the direct calcination method, the sol-gel method is a wet chemical technique in which a precursor containing doped ions can be mixed homogeneously at the atomic level.Thus, the sol-gel technique is lauded for its distinctive ability to regulate the morphology and structure of the material by fine-tuning the synthesis parameters, yielding products of high purity, nanosize, and well-controlled stoichiometry.Xiang's team [85] introduced an enhanced sol-gel approach for the synthesis of Na 0.44 MnO 2 /Mn 2 O 3 composites.They initiated the process by mixing a manganese acetate solution with a sodium citrate solution to form metal chelates.To facilitate the coordination of manganese ions and limit their hydrolysis rate, the pH of the mixture was delicately adjusted with an ammonium hydroxide solution.After a reaction period of 4 h at 80 • C, a loose precursor was obtained through freeze-drying, which was then subjected to a calcination process to yield the final composite material.Parkin et al. [86] prepared potassium permanganate and D (+)-glucose solutions separately.After rapid mixing and subsequent cooling, a brown gel was formed.This gel, once dried and calcined at 400 • C, was transformed into sodium birnessite (K 0.28 MnO 2 ).Unfortunately, the sol-gel method usually needs to use organic acids as chelating agents, and the decomposition of the organic component, solvent evaporation, and gelation require extra energy consumption, which will increase the cost of the product.

Other Methods
Apart from the above-summarized synthesis methods, several other strategies, including the ion exchange method and electrodeposition method, have also been reported in recent years to construct heteroatom-doped Mn x O y materials.For example, Dai et al. [87] synthesized a porous H x Mn 2 O 4 cathode material by using a cation exchange method.They first prepared ZnMn 2 O 4 by coupling the co-precipitation and calcination treatment methods.After soaking ZnMn 2 O 4 in 0.5 M H 2 SO 4 , the Zn 2+ ions in a ZnMn 2 O 4 template were substituted by H + through the Jahn-Teller disproportionation reaction of the Mn 3+ ions and ZnO 4 tetragonal distortion, yielding a distinctive crystal structure with remarkable electrochemical performance.Liu et al. [88] prepared a Ce-doped MnO 2 cathode by utilizing acetylene-black-modified carbon cloth as the substrate for the electrodeposition.After the electrodeposition, the Mn 2+ and Ce 3+ ions in the electrolyte were oxidized and coated on the surface of carbon cloth fibers.The presence of Ce ions can enlarge the Zn 2+ transport channel, accelerate the ion/electron migration, and stabilize the structure, thus improving the electrochemical performance.

The Role of Doping Engineering
Currently, in order to promote the commercialization of Mn-based cathodes, various modification technologies have been proposed to address their drawbacks, including defect engineering [47,89,90], pre-embedding engineering [91][92][93][94], surface engineering [95][96][97], and composite construction [98][99][100].The fabrication of defects can significantly enhance the capacity and reaction kinetics of cathodes by providing additional sites and regulating the electron and crystal structure.However, the prevailing research mainly focuses on single defects, in which it is difficult to achieve precise control of the defect site and concentration.In addition, it has not been determined whether the introduction of defects will adversely affect the crystal structure during battery cycling.Pre-embedding engineering refers to the insertion of other atoms or small molecules into electrode materials, which can enlarge the interlayer spacing, reinforce the crystal phase, and enhance conductivity.However, the most commonly used method for pre-embedding is hydrothermal technology, which is incompatible with large-scale manufacturing and rapid preparation.In addition, preembedded engineering is not universal, and a large number of pre-embedded intercalation agents could alter the layer structure and realign the main layer, resulting in the generation of non-layered fresh phases and the loss of the inherent advantages of the layer structure.Surface engineering refers to coating the electrode material with other highly conductive materials, including graphene, carbon nanotubes, MXenes, conductive polymers, and metal oxides, to improve the conductivity and increase the active sites in the cathode, as well as to protect the material.It is a popular strategy to solve problems including the poor reaction kinetics, structural collapse, and cathode dissolution of Mn.However, the transfer kinetic relationship between the electrolyte and the coating layer, the reaction mechanism, and the changes in physical and chemical properties need to be further investigated.Different from surface engineering, the composite construction strategy offers more patterns, including laminated, core-shell, and sandwich structures.Although the combination of a manganesebased cathode and coating layer is capable of imparting new properties to the cathode and enhancing the advantages of single materials, it also presents challenges such as reducing the volume energy density and increasing the cost.
Doping engineering can adjust the lattice parameters, strengthen the lattice structure, and alleviate the structural damage and untoward reactions through inhibiting cation mixing, lattice distortion, ion migration, etc. [101][102][103][104]. Specifically, heteroatom doping can not only induce unit cell expansion, improving the ion transport path, but can also induce charge redistribution, promoting electron migration.Based on the structure-activity relationship between the doping strategy and the performance of AZIBs, four aspects are classified (Figure 4): enhancing the electron and ion conductivity, increasing the electrochemical active sites, accelerating the reaction kinetics, and maintaining the stability of the structure [105][106][107].
the main layer, resulting in the generation of non-layered fresh phases and the loss of the inherent advantages of the layer structure.Surface engineering refers to coating the electrode material with other highly conductive materials, including graphene, carbon nanotubes, MXenes, conductive polymers, and metal oxides, to improve the conductivity and increase the active sites in the cathode, as well as to protect the material.It is a popular strategy to solve problems including the poor reaction kinetics, structural collapse, and cathode dissolution of Mn.However, the transfer kinetic relationship between the electrolyte and the coating layer, the reaction mechanism, and the changes in physical and chemical properties need to be further investigated.Different from surface engineering, the composite construction strategy offers more patterns, including laminated, core-shell, and sandwich structures.Although the combination of a manganese-based cathode and coating layer is capable of imparting new properties to the cathode and enhancing the advantages of single materials, it also presents challenges such as reducing the volume energy density and increasing the cost.
Doping engineering can adjust the lattice parameters, strengthen the lattice structure, and alleviate the structural damage and untoward reactions through inhibiting cation mixing, lattice distortion, ion migration, etc. [101][102][103][104]. Specifically, heteroatom doping can not only induce unit cell expansion, improving the ion transport path, but can also induce charge redistribution, promoting electron migration.Based on the structure-activity relationship between the doping strategy and the performance of AZIBs, four aspects are classified (Figure 4): enhancing the electron and ion conductivity, increasing the electrochemical active sites, accelerating the reaction kinetics, and maintaining the stability of the structure [105][106][107].

Enhancing Intrinsic Electron/Ion Conductivity
The introduction of other elements into the manganese-based cathode may change its charge and spin distribution, as well as the band gap, resulting in a significant change in its intrinsic conductivity (Figure 4a) [108].Zhou et al. [109] used first-principles calculations to investigate the change in the density of states of α-MnO2 with a 1 × 1 × 3 periodic

Enhancing Intrinsic Electron/Ion Conductivity
The introduction of other elements into the manganese-based cathode may change its charge and spin distribution, as well as the band gap, resulting in a significant change in its intrinsic conductivity (Figure 4a) [108].Zhou et al. [109] used first-principles calculations to investigate the change in the density of states of α-MnO 2 with a 1 × 1 × 3 periodic supercell and found that V doping increases the Fermi level of α-MnO 2 and shifts it toward the bottom of the conduction band.In addition, the band gap is narrowed due to the generation of impurity peaks.Therefore, it is found that the introduction of V increases the conductivity of MnO 2 .Rao et al. [110] investigated the diffuse reflectance spectra of Zn-doped δ-MnO 2 and found that with an increasing Zn content, the band gap increases from 2.3 eV (5 mol % doping) to 2.37 eV (10 mol % doping).This variation in the band gap has a strong correlation with the change in the Zn doping amount, which ultimately manifests in an increase in the overall electronic conductivity.Song et al. [111] discovered that the incorporation of Co into MnO 2 can introduce holes and improve the conductivity by introducing a new electronic state around the Fermi level, which facilitates the electron migration between Mn 4+ and Mn 3+ , enhances the concentration of redox active sites, and ultimately improves the contribution rate of pseudocapacitance in MnO 2 .

Increasing Electrochemical Active Sites
Increasing the number of electrochemically active binding sites by doping treatment is mainly achieved from two aspects (Figure 4b).First, the introduction of heteroelements can activate more active sites for redox reactions and plug in pseudocapacitance [106,112].Sun et al. [35] found that the doping of S in MnO 2 under non-equilibrium conditions, taking high temperature and surface sites as examples, can generate a large number of oxygen defects within the structure or further create an amorphous phase on the surface or edge.On the one hand, this can improve the ion and electron transfer within the structure of the cathode.On the other hand, the amorphous region accelerates the ion transfer in the electrolyte/electrode interface, provides numerous pseudocapacitive active sites, and contributes to the capacity.Zhao et al. [113] found that the Zn doping can change the crystal structure of MnO 2 , referring to more atomic dislocations observed by transmission electron microscopy, which are used as active sites for ion absorption in order to accelerate the electrochemical activity of the active material.Moreover, in the process of preparing manganese-based cathodes, the introduction of impurity elements can induce a change in the morphology and structure, which increases their specific surface and provides abundant active sites for electrochemical reactions.

Promoting Diffusion Kinetics
The electrostatic shielding effect of crystal water can lower the energy barrier, expand the tunnel space of the material, and shorten the diffusion path of electrons and ions; this is favorable in accelerating the diffusion kinetics in manganese-based cathodes (Figure 4c).Fan et al. [114] prepared Na-doped MnO 2 material by the co-precipitation method and found that the charge shielding effect generated through structural water can promote the rapid transfer of ions within the MnO 2 crystal.The amorphous characteristics of the cathode also provide more active sites and reduce the ion diffusion pathway.Fang et al. [115] found that the spacing expansion of the tunnel structure in α-MnO 2 originating from K + intercalation consciously generates extra space for the effective transport of H + and Zn 2+ in the charge/discharge process, ensuring fast diffusion kinetics of the cation.Yan et al. [116] studied the diffusion barrier path with the lowest energy of Zn 2+ in Fedoped MnO 2 and MnO 2 through density functional theory (DFT) calculations.Apparently, the diffusion of Zn 2+ along the MnO 2 cathode encounters the barrier of 380 meV, while the Fe-doped MnO 2 cathode encounters a lower barrier of 260 meV, indicating that the low-energy-barrier cathode exhibits faster diffusion kinetics than the high-energy-barrier cathode.Compared with MnO 2 , the Fe replacement rearranges the allocation of the electrostatic potential surface, resulting in a topical maximum under an inferior potential, which promotes ion and electron transport, as well as reduces the energy barrier.

Maintaining Structural Stability
Cycle life is one of the most important criteria for evaluating secondary batteries.However, AZIBs have faced the challenge of rapid capacity degradation.The structural damage in the charging/discharging process is thought to be the main reason for the poor cycle life of manganese-based AZIBs, including the dissolution of manganese and irreversible phase transition.Xu et al. [117] obtained uniformly Cu-doped MnO 2 by the heat treatment of MOF precursors and found that the ratio of Mn 4+ /Mn 3+ in the undoped sample was lower, indicating that Cu-doped MnO 2 contains less Mn 3+ and reduces Mn dissolution and Jahn-Teller distortion.Huang et al. [28] successfully prepared Ni-doped Mn 2 O 3 by co-precipitation and calcination processes.DFT calculations revealed that the formation energy of Mn 2 O 3 could be reduced and the Mn-O bond of Mn 2 O 3 could be effectively stabilized by Ni doping, thus enhancing the structural stability of Mn 2 O 3 .Similarly, Hui et al. [118] found that the doping with low-valent Zn 2+ replaces the position of Mn and adjusts the electronic structure near the Mn-O bond, thereby accelerating the asymmetric coupling between the O 2− and Mn 4+ and strengthening the structural stability.Therefore, alleviating the dissolution of manganese ions or forming a strong interaction by forming strong ionic bonds is considered to be an efficient strategy to increase the stability of manganese-based oxide cathodes (Figure 4d).

MnO 2
Among the Mn x O y materials, MnO 2 is the most extensively studied cathode in AZIBs [37,119].MnO 2 has different crystal structures, mainly consisting of α-, β-, γ-, δ-and ε-MnO 2 [120][121][122].MnO 2 -based cathodes offer several advantages consisting of the natural high abundance of Mn-contributed low cost, low-toxicity-contributed environmental safety, good electrochemical capacity [123][124][125], and capability for multi-electron transfer reactions.However, the commercial application of MnO 2 cathodes of AZIBs faces challenges such as manganese dissolution, irreversible phase transition, and inferior electronic and ionic conductivity [126].As one of the effective cathode modification strategies, doping engineering has significant value in enhancing the rate property and cycling stability in MnO 2 cathodes.Elemental doping serves to alleviate the phase transformation and volume fluctuation in cathodes, thus ensuring their structural stability throughout the cycle.Moreover, doping can introduce defects into the structure, resulting in increased active storage sites for ions and protons.In addition, the lattice expansion and charge redistribution generated by doping are conducive to accelerating the transfer rate of ions and electrons and decrease the electrostatic repulsion between Zn 2+ and MnO 2 [35].According to the difference in crystal types, the synthesis method, electrochemical performance, and internal improvement mechanism of doped α-, δ-, β-, ε-, and γ-MnO 2 are summarized and analyzed.

α-MnO 2
The large spacing and stable tunnel structure of α-MnO 2 facilitate the rapid and reversible intercalation/de-intercalation of H + and Zn 2+ , endowing AZIBs with high specific capacity and moderate discharge voltage [127].However, the slow ion diffusion caused by the poor conductivity of α-MnO 2 and the severe capacity decay and poor rate performance originating from the inevitable dissolution of Mn limit the application of α-MnO 2 in AZIBs.Numerous studies have shown that the ion diffusion kinetics, electronic/ionic conductivity, and structural stability of MnO 2 can be enhanced through using doping engineering to improve the cycling stability and rate property of the material.
In terms of optimizing the reaction diffusion kinetics, heteroatom doping can increase the tunnel size of α-MnO 2 and provide a larger diffusion space for the insertion or deinsertion of Zn 2+ .Xu et al. [128] synthesized polypyrrole-encapsulated and Fe 3+ -doped α-MnO 2 composites by chemical precipitation and acid-catalyzed pyrrole polymerization processes.By comparing the displacement of XRD characteristic peaks, it can be found that the pre-intercalation of Fe 3+ can increase the interlayer space of α-MnO 2 , thereby increasing the rate of Zn 2+ intercalation/de-intercalation (Figure 5a).Lin et al. [50] introduced Co 2+ and abundant oxygen vacancies into two-dimensional layered α-MnO 2 nanofibers (Coα-MnO 2 ) through the hydrothermal process and plasma technology, respectively.It was found that the doping of Co 2+ can not only flexibly control the interlayer spacing of MnO 2 and create more space for the transport of Zn 2+ but can also enhance the stability of the α-MnO 2 -layered skeleton by buffering the volume variation in the charging/discharging process.Therefore, Co-doped α-MnO 2 exhibits excellent rate performance.As current density is restored from 5 to 1 A g −1 , the cathode still maintains a capacity of 249 mAh g −1 .
The ion diffusion energy barrier can be effectively adjusted by doping engineering to reinforce the ionic diffusion coefficient.Li et al. [129] innovatively synthesized Mg 2+ -doped α-MnO 2 composites with abundant oxygen defects via a simple hydrothermal method.Electrochemical performance characterizations and DFT calculations confirm that the insertion of Mg 2+ efficiently reduces the charge transfer resistance, polarization, and Zn 2+ diffusion barrier and improves the structural stability of α-MnO 2 .Therefore, the Mg-α-MnO 2 cathode can maintain a high capacity of 311 mAh g −1 at 600 mA g −1 after 700 cycles (Figure 5b).Additionally, Guo et al. [130] also found that the doping of metallic elements enhances the reaction kinetics of electrode materials by studying the cyclic voltammetry curve of Al-doped MnO 2 .The results demonstrate that Al-doped α-MnO 2 exhibits a more intense oxidation/reduction current than α-MnO 2 .Simultaneously, the voltage gap of Al-doped α-MnO 2 (0.17 and 0.43 V) is decreased compared to α-MnO 2 (0.22 and 0.48 V).As displayed in Figure 5c, Al-doped MnO 2 has more excellent electrochemical reactivity and reaction kinetics.
that the pre-intercalation of Fe 3+ can increase the interlayer space of α-MnO2, thereby increasing the rate of Zn 2+ intercalation/de-intercalation (Figure 5a).Lin et al. [50] introduced Co 2+ and abundant oxygen vacancies into two-dimensional layered α-MnO2 nanofibers (Co-α-MnO2) through the hydrothermal process and plasma technology, respectively.It was found that the doping of Co 2+ can not only flexibly control the interlayer spacing of MnO2 and create more space for the transport of Zn 2+ but can also enhance the stability of the α-MnO2-layered skeleton by buffering the volume variation in the charging/discharging process.Therefore, Co-doped α-MnO2 exhibits excellent rate performance.As current density is restored from 5 to 1 A g −1 , the cathode still maintains a capacity of 249 mAh g −1 .
The ion diffusion energy barrier can be effectively adjusted by doping engineering to reinforce the ionic diffusion coefficient.Li et al. [129] innovatively synthesized Mg 2+ -doped α-MnO2 composites with abundant oxygen defects via a simple hydrothermal method.Electrochemical performance characterizations and DFT calculations confirm that the insertion of Mg 2+ efficiently reduces the charge transfer resistance, polarization, and Zn 2+ diffusion barrier and improves the structural stability of α-MnO2.Therefore, the Mg-α-MnO2 cathode can maintain a high capacity of 311 mAh g −1 at 600 mA g −1 after 700 cycles (Figure 5b).Additionally, Guo et al. [130] also found that the doping of metallic elements enhances the reaction kinetics of electrode materials by studying the cyclic voltammetry curve of Al-doped MnO2.The results demonstrate that Al-doped α-MnO2 exhibits a more intense oxidation/reduction current than α-MnO2.Simultaneously, the voltage gap of Al-doped α-MnO2 (0.17 and 0.43 V) is decreased compared to α-MnO2 (0.22 and 0.48 V).As displayed in Figure 5c, Al-doped MnO2 has more excellent electrochemical reactivity and reaction kinetics.It is well known that doping engineering can introduce new energy levels and energy band structures or affect the formation of electron-hole pairs, thereby changing the electronic structure in the material and ultimately achieving changes in the ion/electron conductivity of the cathode.Cao et al. [131] constructed Ga-doped α-MnO 2 nanowires and applied them to AZIBs, showing significantly improved electrochemical performance.After 200 cycles under 0.2 A g −1 , an excellent capacity of 205 mAh g −1 can still be obtained.Ga can effectively adjust the electronic distribution of α-MnO 2 and reduce its gap.On the basis of the electron density distribution, it can be seen that Ga doping causes the electron rearrangement of α-MnO 2 , resulting in the polarization of the electron cloud of O, thereby improving the conductivity of the material (Figure 5d,e).Similarly, Yuan et al. [132] demonstrated the effect of Bi doping on the conductivity by calculating the density of states.As exhibited in Figure 5f, the Fermi level separates the conduction and valence band in the original MnO 2 , and the band gap is 0.69 eV.However, due to the enhancement of the total density state around the Fermi level, the energy gap in Bi-doped MnO 2 is reduced to 0 eV and a further Fermi level permeates the energy band, indicating that Bi-doped MnO 2 is a half-metal.Consequently, the conductivity in Bi-doped MnO 2 was enhanced by the Bi doping.In addition to the influence on ion/electron conductivity and reaction kinetics, the doping of heteroelements also performs a significant role in improving the structural stability of α-MnO 2 during the charge/discharge process.Li et al. [134] adopted the mild hydrothermal method to simultaneously introduce oxygen vacancies and K + into the lattice of α-MnO 2 .The synchrotron radiation experiments and DFT calculations show that the insertion of K + not only regulates the type of metal bonds in α-MnO 2 but also changes the average charge distribution of O 2− .Doping with K + further stabilizes the skeleton structure of α-MnO 2 , which prolongs the cycling stability of the cathode.The insertion of extra oxygen vacancies during the K + doping process leads to the formation of α-MnO 2 , which can increase the electrochemical reaction active sites and the conductivity of the cathode.Therefore, K-α-MnO 2 exhibits an electrochemical specific capacity up to 250.9 mAh g −1 under a current density of 0.2 C and maintains a capacity of 300.2 mAh g −1 after 100 cycles.Lan's group [135] synthesized Cu-doped α-MnO 2 through a mild hydrothermal technique.By comparing the cyclic voltammetry of samples before and after doping in the AZIBs, it was found that the redox peak potential of Cu-doped α-MnO 2 has a smaller offset, indicating that Cu doping can alleviate the polarization of α-MnO 2 and strengthen the structural stability.Liu et al. [133] investigated the electrochemical performance of α-MnO 2 in the process of H + /Zn 2+ intercalation into hydrated ZIBs by replacing Mn 4+ with transition metals through DFT. Figure 5g,h show the evolution curves of volume change and intercalation state of undoped samples and V-or Cr-doped samples during H + and Zn 2+ intercalation, respectively.The results illustrate that the substituents contribute to cycling performance and capacity retention.However, as a doping element in α-MnO 2 , Cr is more efficient than V in terms of improving discharge voltage, capacity, and cycling stability.The excellent promotion effect of Cr is attributed to the singular atomic and electronic structure of Cr 4+ /Cr 3+ .As an electron acceptor, Cr 4+ is easier to reduce than Mn 4+ , which hinders the generation of metastable Mn 3+ and Mn 2+ centers.Mn 3+ is less stable than Cr 3+ , the former stabilizing neighboring Mn ions to a large extent.
In addition, the electrochemical property of α-MnO 2 can also be enhanced by doping engineering.For instance, Lu's team [136] proposed a dual-element-doped α-MnO 2 as a high-performance cathode for AZIBs.In this paper, Ti and Ni co-inserted α-MnO 2 (TiNi-α-MnO 2 ) was synthesized by a simple hydrothermal strategy in the presence of Ti 3 C 2 X and Ni 2+ , which was employed as a cathode for AZIBs.The insertion of Ti enables multivalent changes (Ti 4+ /Ti 2+ ), which are conducive to increasing the specific capacity of the electrode.The lattice distortion caused by Ni can accelerate the Grothus-like proton transfer and enhance the specific capacity of the cathode.Therefore, the TiNi-α-MnO 2 cathode exhibits large reversible capacity and excellent rate capability.Alfaruqi et al. [137] synthesized V-doped α-MnO 2 (V-α-MnO 2 ) by a simple redox process at room temperature and investigated the electrochemical performance in AZIBs.In the X-ray diffraction pattern, the isotropic displacement of the derivative peak in V-α-MnO 2 relative to pure MnO 2 illustrates the successful insertion of V into the lattice of MnO 2 .V doping simultaneously increases the specific surface area and electronic conductivity in the MnO 2 cathode.The Zn 2+ storage performance test reveals that V-α-MnO 2 exhibits a higher discharge capacity (266 mAh g −1 ) than pure MnO 2 (213 mAh g −1 ).During the long-term charge/discharge process, the capacity maintenance rate of V-α-MnO 2 (31%) is higher than that of pure MnO 2 , confirming its excellent cycling performance.
In summary, the elemental doping of α-MnO 2 results in the following modification effects: reducing the charge transfer resistance; increasing the ion diffusion rate; promoting the transport of electrons, protons, and Zn 2+ ; increasing the electrochemical active sites; alleviating the dissolution of the cathode; and stabilizing the tunnel structure in the cathode.Therefore, it is of great significance to explore the doping engineering of α-MnO 2 .

δ-MnO 2
The unique two-dimensional layered structure and large interlayer spacing of δ-MnO 2 are conducive to the intercalation/de-intercalation of H + and Zn 2+ , granting its good specific capacity [62,127].However, the intrinsic conductivity of δ-MnO 2 is low, and Mn 2+ dissolution and volume shrinkage are prone to occur in δ-MnO 2 -based cathodes during the charging/discharging cycle [138][139][140].Therefore, it is imperative to modify δ-MnO 2 for its application in AZIBs.Researchers have extensively explored the doping engineering of δ-MnO 2 , mainly including cation doping and anion doping.There are many reports on the cation doping modification of δ-MnO 2 , containing alkali metals [140], magnetic transition metals [141], another Mg [142] in the third cycle, other Cu [143] and Zn [144] in the fourth cycle, Mo [145] and Ag [146] in the fifth cycle, and Ce [51] and Bi [143] in the sixth cycle.There are a few reports on anion doping modification, including F [147] and S [35].
Qi et al. [140] used a simple room-temperature redox method to pre-intercalate alkali metals including Li + , Na + , and K + into the interlayer of MnO 2 , which was utilized as a cathode in AZIBs, and explored their different effects on the electrochemical property and energy storage mechanism in AZIBs.The electrochemical test results indicate that the specific capacity, rate capability, and cycling stability of the cathode are proportional to the radius of the alkali metal.The larger the radius of the doping ions, the larger the interlayer spacing of the cathodes and the easier the diffusion of Zn 2+ .The Zn 2+ diffusion barriers of Li-, Na-, and K-δ-MnO 2 obtained from DFT are 0.7, 0.5, and 0.5 eV (Figure 6a), respectively, indicating that K-δ-MnO 2 is able to contribute more excellent electrochemical kinetics.Yu et al. [51] synthesized a Ce-δ-MnO 2 @CS composite composed of a mesoporous carbon core and Ce-doped MnO 2 nanosheet shell by a simple low-temperature liquid-phase reaction method.Ce serves as a pillar to expand the interlayer spacing of MnO 2 , which can promote the intercalation/de-intercalation of Zn 2+ .The network structure of mesoporous carbon spheres and unique core-shell structure offers an effective pathway for the conduction of ions and electrons.The optimized Ce-δ-MnO 2 @CS electrode demonstrates significantly improved energy density and power density (Figure 6b).With the mechanical flexibility, the Ce-δ-MnO 2 @CS core-shell composite is expected to be applied in wearable flexible electronic devices.Li et al. [148] pre-embedded Cu and Bi double transition metal ions between δ-MnO 2 layers (CuBi-δ-MnO 2 ) through a one-step hydrothermal strategy, which served as a cathode for AZIBs.They also used a DFT calculation method to compare the diffusion barriers of Zn 2+ in MO and CuBi-δ-MnO 2 .The formation energy of origin Zn 2+ transfer paths between the same layer and different layers in CuBi-δ-MnO 2 are −4.71 and −5.94 eV, respectively.The diffusion barriers of Zn 2+ in CuBi-δ-MnO 2 are 1.1066 and 0.8251 eV when it is in the same layer and different layer with Cu/Bi ions, respectively (Figure 6c).Both of them are lower than in δ-MnO 2 (2.845 eV).The impurity doping can introduce numerous defects in δ-MnO 2 and embed more Zn 2+ as an active site.Wu's group [146] employed a mild one-step hydrothermal method to generate Ag-inserted δ-MnO 2 composites (Ag-δ-MnO 2 ) with different concentrations as cathodes of AZIBs.The doping of Ag + should introduce abundant oxygen defects and act as an active storage site for Zn 2+ , which facilitates Zn 2+ migration.Electrochemical characterization reveals that when the doping concentration is 1.12 wt %, Ag-δ-MnO 2 exhibits the best specific capacity and cycling stability.After 1000 cycles, the discharge capacity can still retain 114 mAh g −1 (Figure 6d).Yan et al. [141] anchored Fe 3+ , Co 2+ , and Ni 2+ ions between the layers of δ-MnO 2 (Fe-, Co-, Ni-δ-MnO 2 ) by a dual-field in situ induction process, which selectively accelerated the transport of either H + or Zn 2+ .The study discovered that the insertion of Fe 3+ preferentially promotes the transfer of Zn 2+ , and the insertion of Co 2+ and Ni 2+ preferentially promotes the transfer of H + .The doping of magnetic transition metal ions into the oxygen vacancies of δ-MnO 2 can buffer the structural change caused by lattice distortion during the charging/discharging process, increase the active storage sites of H + and Zn 2+ , and accelerate the ions' diffusion.The results show that Fe-δ-MnO 2 still exhibits a high capacity of more than 110 mAh g −1 after 500 cycles.However, the discharge capacity of pure δ-MnO 2 was reduced to less than 25 mAh g −1 after 250 cycles (Figure 6e).Sun's group [35] prepared S-doped δ-MnO 2 by a low-temperature vulcanization method and investigated its zinc storage performance.It was found that S-doped δ-MnO 2 had a higher discharge specific capacity and pseudocapacitance contribution rate than pure δ-MnO 2 .They believe that this is due to the oxygen defects generated by S doping on the amorphous surface of δ-MnO 2 , improving the Zn 2+ storage site, and this special amorphous region gives ions the ability to enter the electrolyte/electrode interface and contribute to the capacitance.6c).Both of them are lower than in δ-MnO2 (2.845 eV).The impurity doping can introduce numerous defects in δ-MnO2 and embed more Zn 2+ as an active site.Wu's group [146] employed a mild one-step hydrothermal method to generate Ag-inserted δ-MnO2 composites (Ag-δ-MnO2) with different concentrations as cathodes of AZIBs.The doping of Ag + should introduce abundant oxygen defects and act as an active storage site for Zn 2+ , which facilitates Zn 2+ migration.Electrochemical characterization reveals that when the doping concentration is 1.12 wt %, Ag-δ-MnO2 exhibits the best specific capacity and cycling stability.After 1000 cycles, the discharge capacity can still retain 114 mAh g −1 (Figure 6d).Yan et al. [141] anchored Fe 3+ , Co 2+ , and Ni 2+ ions between the layers of δ-MnO2 (Fe-, Co-, Ni-δ-MnO2) by a dual-field in situ induction process, which selectively accelerated the transport of either H + or Zn 2+ .The study discovered that the insertion of Fe 3+ preferentially promotes the transfer of Zn 2+ , and the insertion of Co 2+ and Ni 2+ preferentially promotes the transfer of H + .The doping of magnetic transition metal ions into the oxygen vacancies of δ-MnO2 can buffer the structural change caused by lattice distortion during the charging/discharging process, increase the active storage sites of H + and Zn 2+ , and accelerate the ions' diffusion.The results show that Fe-δ-MnO2 still exhibits a high capacity of more than 110 mAh g −1 after 500 cycles.However, the discharge capacity of pure δ-MnO2 was reduced to less than 25 mAh g −1 after 250 cycles (Figure 6e).Sun's group [35] prepared Sdoped δ-MnO2 by a low-temperature vulcanization method and investigated its zinc storage performance.It was found that S-doped δ-MnO2 had a higher discharge specific capacity and pseudocapacitance contribution rate than pure δ-MnO2.They believe that this is due to the oxygen defects generated by S doping on the amorphous surface of δ-MnO2, improving the Zn 2+ storage site, and this special amorphous region gives ions the ability to enter the electrolyte/electrode interface and contribute to the capacitance.The defects introduced by this special strategy can not only provide abundant active sites to insert Zn 2+ but can also enhance the ionic/electronic conductivity of δ-MnO 2 .Di's group [142] synthesized Mg 2+ -doped δ-MnO 2 (Mg-δ-MnO 2 ) via a mild hydrothermal process and employed it as a cathode for AZIBs.Oxygen vacancies are also introduced during the Mg 2+ doping, which significantly improves the electronic conductivity and ion diffusion coefficient of δ-MnO 2 .In particular, they showed that Mg-doped δ-MnO 2 with oxygen vacancies displays the lowest band gap (0.18 eV, Figure 6f) by DFT calculations.At the same time, new electronic states appear around the Fermi level, indicating that the inherent electron transfer efficiency and electrochemical reactivity have been improved.The results obtained from electrochemical impedance spectroscopy indicate that the charge transfer resistance of Mg-MnO 2 is lower than that of MnO 2 (Figure 6g).Besides the effect of the introduced oxygen vacancies, the band gap change caused by doping can also enhance its electronic/ionic conductivity.Ding's team [149] calculated the density of states of δ-MnO 2 and Cr 0.02 Mn 0.98 O 2 by DFT and found that, compared with δ-MnO 2 , the introduction of Cr causes the density of states in δ-MnO 2 to move toward the Fermi level, illustrating that the presence of Cr enlarges the dedication of spin-down electrons to the density of states around the Fermi level, resulting in a band gap decrease.Therefore, the doping of Cr can efficiently accelerate the electron immigration of δ-MnO 2 , further increasing the conductivity of the electrode.
The doping of other metals can also adjust the ionic bonding properties of δ-MnO 2 , thereby improving the structural stability of δ-MnO 2 and achieving a longer service life in AZIBs.Wang et al. [147] synthesized highly oriented F-doped δ-MnO 2 nanosheets (F-δ-MnO 2 ) as a cathode for AZIBs by the lava method combined with annealing post-treatment.F doping can not only stabilized the [MnO 6 ] octahedral structure by forming F-Mn chemical bonds but also ensured the structural stability of δ-MnO 2 .The charge compensation effect caused by F doping was verified by the XPS test, that is, F doping can enhance the Mn 3+ concentration.Therefore, the dissolution of Mn active substances was inhibited by adjusting the proportion of Mn 3+ /Mn 4+ through F doping.F-doped δ-MnO 2 exhibits excellent rate performance, with discharge capacities of 288, 240, 160, 122, and 84 mAh g −1 under current densities of 100, 200, 500, 1000, and 2000 mA g −1 , respectively.When the current density was restored to 100 mA g −1 again, the F-doped δ-MnO 2 still maintained a high capacity of 280 mAh g −1 (Figure 6h).These results demonstrate that doping engineering can promote the structural distortion of the [MnO 6 ] octahedron, improve the reversibility of the electrochemical reaction, and thus maintain the long-term cycling stability of the material structure.Sun's group [150] investigated the impact of doping elements on the cycling stability of Cr and Ni co-doped δ-MnO 2 through comprehensive structural and performance characterization.The results show that Cr 4+ aggravates the Jahn-Teller distortion of Mn(III)O 6 and promotes the dissolution of CrNi-ZnMn 2 O 4 into Mn 2+ .The doped Cr 3+ can be used as 'scissors' to eliminate the low activity MnO 2 accumulated by the disproportionation of dissolved Mn 3+ .Therefore, the Cr and Ni elements enable the CrNi-MnO 2 to undergo a highly reversible MnO 2 /Mn 2+ redox reaction and maintain the structural integrity after long-term cycling stability testing.In subsequent work by the same research group, Mo was found to play a similar role in Mo-doped δ-MnO 2 [145].
In summary, the doping modification of δ-MnO 2 has the following improvement effects: the doping of metal or non-metal elements will simultaneously produce oxygen vacancies and expand the interlayer spacing of δ-MnO 2 , and both the doped atom and vacancy can simultaneously increase the electron mobility of the bulk material while reducing the ion diffusion barrier, thus promoting the reaction kinetics of the cathode; moreover, doping modification can buffer the structural change caused by lattice distortion in the charge/discharge process, then strengthen the cycling stability while maintaining the stability of the skeleton structure.Therefore, it is of great importance to explore the doping engineering of δ-MnO 2 .

β-MnO 2 , ε-MnO 2 , and γ-MnO 2
Although the open channels of β-MnO 2 with thermodynamic stability [122] can accommodate a reasonable amount of Zn 2+ , the small size of the channels hinders the ion diffusion during the cycling process, resulting in the slow reaction kinetics of the β-MnO 2 cathode.The narrow tunnel structure of β-MnO 2 reduces the active sites for electrochemical reactions, resulting in the low specific capacity of the β-MnO 2 cathode [151,152].In order to solve these challenges and apply β-MnO 2 to the cathode in AZIBs, a large number of papers on doped β-MnO 2 have been reported in recent years.One group synthesized Eu-β-MnO 2 by doping rare earth element Eu into β-MnO 2 through a hydrothermal process and used it as a cathode in AZIBs.Eu has good conductivity and stable chemical properties, which is one of the best choices for the doping modification of β-MnO 2 .It is found that the intercalation of Eu enlarges the interlayer spacing of β-MnO 2 , promotes the diffusion of H + and Zn 2+ , and maintains the structural stability of β-MnO 2 .Eu-β-Mn O2 has a high specific capacity at low current density and can still display a discharge specific capacity of 254 mAh g −1 after 128 cycles.Doping manganese oxide with rare earth elements is one of the research hotspots in the modification of AZIB cathode materials [153].
The dense and limited three-dimensional tunnel structure in ε-MnO 2 hinders the intercalation/de-intercalation of protons and cations, which leads to the low conductivity of the ε-MnO 2 cathode [154].As an effective strategy to improve the electrochemical activity of electrode materials, it is of great importance to explore the doping engineering of ε-MnO 2 .Zhang et al. synthesized Cu 2+ -doped ε-MnO 2 porous nanostructures (Cu-ε-MnO 2 ) by a simple one-step electrodeposition process for an AZIB cathode.The insertion of Cu 2+ increases the spacing of the δ-MnO 2 tunnel structure and increases the diffusion rate of electrons and ions.The micropores promote charge storage and ion adsorption, and the mesopores provide ion transport channels.Cu-ε-MnO 2 has better electrochemical performance than pure MnO 2 , and under a current density of 0.2 A g −1 , the discharge specific capacity can reach 235 mAh g −1 [155].
The multi-tunnel structure of γ-MnO 2 is conducive to the intercalation/de-intercalation of cations, and the formed porous structure can offer abundant active sites for electrochemical reactions [58].However, the irregular arrangement of γ-MnO 2 crystal cells leads to low crystallinity, which contributes to the uneven distribution of potential and irreversible phase transition during the charging/discharging process.Hence, it is very important to change the crystal structure of γ-MnO 2 by doping modification to improve its Zn 2+ storage performance.Wang's group synthesized a Ni 2+ -doped γ-MnO 2 (Ni-γ-MnO 2 ) as a highly active cathode material for AZIBs by employing a mild one-step electrodeposition approach [156].It was found that the doping of Ni 2+ reduces the diffusion barrier of protons, which is beneficial for the insertion of ions into the tunnel structure and accelerates the reaction kinetics of the battery.DFT calculations show that the insertion of Ni 2+ improves the electronic conductivity between [MnO 6 ] octahedra.Therefore, the Ni-γ-MnO 2 cathode exhibits excellent rate performance (56 mAh g −1 at a current density of 10 A g −1 ) and a long cycle life (more than 100% capacity retention after 11,000 cycles at 3.0 A g −1 ).

MnO
As the simplest oxide among Mn x O y -based cathode materials, the storage mechanism of MnO involves the reversible co-intercalation/de-intercalation of H + and Zn 2+ and their chemical conversion.Although a higher theoretical capacity, higher conversion voltage, and higher energy density make MnO more competitive, it also has limitations such as fewer active sites, poor electronic conductivity, and poor cycling performance.This section primarily focuses on the impact of MnO doping engineering on enhancing the electrochemical performance of AZIBs.There are several effective strategies for MnO doping engineering: co-doping to boost intrinsic conductivity, high-entropy doping to improve structural stability, introducing vacancies to increase active sites, inducing changes in the morphology and structure of MnO and enriching the porosity, and mitigating manganese dissolution to enhance electrochemical performance.Therefore, doping engineering has been widely employed to address the aforementioned deficiencies of MnO, thereby improving its practical applicability.
To enhance the Zn 2+ storage capacity of the MnO cathode, Cao's group [157] synthesized Ni-nanoparticle-doped MnO composites (Ni-MnO/PC) that were uniformly anchored on porous carbon through hydrothermal and annealing methods.As shown in Figure 7a,b, Ni-MnO exhibits a stronger Zn 2+ adsorption energy, suggesting a higher affinity for Zn 2+ adsorption.The incorporation of porous carbon provides an abundance of pores and ensures sufficient contact between the cathode and the electrolyte, providing sufficient diffusion pathways for ions.Furthermore, the addition of Ni nanoparticles promotes electron rearrangement, which in turn improves the conductivity of nanomaterials.As shown in Figure 7c, the Zn||Ni-MnO/PC battery exhibits a discharge specific capacity of 347.4 mAh g −1 at a current density of 100 mA g −1 .Even at a higher current density (3000 mA g −1 ), the Ni-doped MnO/PC electrode still maintains a capacity retention rate of more than 90% after long-term cycling, which is superior to MnO/PC and MnO/C.In addition, the team also verified that the introduction of vacancies can effectively increase the distribution of active sites and further improve the electrochemical performance of MnO cathode materials.Chen's group [53] introduced a strategy of Al doping to modify MnO, resulting in the synthesis of Al-MnO materials.These materials can be transformed into orthorhombic manganese ore-structured MnO 2 (R-MnO 2 ) through co-precipitation and calcination processes.Through scanning electron microscope (SEM) images, it can be found that MnO/Al-MnO forms microspheres with diameters in the range of approximately 0.6~0.8µm (Figure 7d,e), and Al is uniformly distributed throughout the sample (Figure 7f).This Al 3+ doping not only introduces an abundance of Mn vacancies but also increases the specific surface area and pore size of MnO.This enhancement improves the cathode's wettability with the electrolyte.Furthermore, it can also reduce the ion transport path within the crystal structure and provide more active sites.Similarly, Liang's group [158] synthesized N-doped MnO through a one-step melamine pyrolysis method.This process introduced oxygen vacancies into the material (Figure 7g).Oxygen vacancies significantly enhance the material's intrinsic electronic conductivity and increase the distribution of electrochemically active sites for Zn 2+ storage.On the other hand, they can also promote the insertion and extraction of Zn 2+ , thus greatly improving the electrochemical performance of the inert MnO.The fabricated N-VO-MnO 1−x cathode demonstrates excellent rate performance (after 600 cycles at 0.5 A g −1 , there is still a retention rate of 90%, Figure 7h).Lei's group [159] doped trace amounts of calcium into manganese monoxide (CMO) using a solid-state reaction, creating a cathode material of AZIBs with rich interfacial chemical bonds.In addition, calcium doping not only optimizes the charge/ion state and electronic band gap but also ensures a reversible phase transition and mitigates the dissolution of Mn from the cathode.Concurrently, the wide lattice spacing of the CMO material not only weakens the interaction force between anions and cations but also provides more space channels for ion migration during the initial cycle, significantly enhancing the diffusion kinetics.Since the MnO cathode material modified by single-ion doping has not yet met expectations, a plethora of research has focused on the advancement of multi-ion doping strategies for the enhancement of MnO cathode materials.Distinct from the conventional single-ion doping approach, Zn/Co co-doped MnO/C was prepared by Chen's group [160] using metal-organic frameworks as precursors and used as an AZIB cathode material.The doping of Zn 2+ enhances the reactivity of MnO, while the incorporation of Co ions boosts the capacity.Moreover, Co ions can also inhibit the Jahn-Teller effect of Mn 3+ in the electrolyte, thereby enhancing structural stability.Benefiting from the synergistic effect of the two doped ions, the ion diffusion rate and conductivity of MnO are remarkably enhanced, thus exhibiting excellent electrochemical performance (Figure 7i,j).Unlike singleion doping, multi-ion doping realizes the in situ bonding of manganese through the close arrangement of different heteroatoms, leading to the formation of robust manganese ion bindings within the crystal cell.Recently, Wang's group [161] prepared Co, Fe, Ni, Cu, and Cr co-doped MnO cathode materials (co-doped MnO) by a high-entropy-doping strategy.The molar contents of the five heteroelements is similar, and they all have the same molar ratio with Mn ions (Mn:X = 28.3:1).The interactions between the metal elements in the co-doped MnO promote a denser overlap of the electron cloud between Mn 2+ and O 2− , which greatly increases the binding energy of the MnO bond.In addition, a large number of oxygen defects introduced by Co, Fe, Ni, Cu, and Cr doping can accelerate the ion transport in the cathode material and enhance the reaction kinetics.Finally, this codoped high-entropy MnO exhibits excellent long-term cycle stability and rate performance (Figure 7k).
In summary, to address these issues (fewer active sites, poor electronic conductivity, and poor cycling performance) with MnO cathode materials, the prevailing strategies include co-doping to enhance intrinsic conductivity and high-entropy doping to bolster structural stability.Through doping engineering, a protective layer is introduced on the Since the MnO cathode material modified by single-ion doping has not yet met expectations, a plethora of research has focused on the advancement of multi-ion doping strategies for the enhancement of MnO cathode materials.Distinct from the conventional single-ion doping approach, Zn/Co co-doped MnO/C was prepared by Chen's group [160] using metal-organic frameworks as precursors and used as an AZIB cathode material.The doping of Zn 2+ enhances the reactivity of MnO, while the incorporation of Co ions boosts the capacity.Moreover, Co ions can also inhibit the Jahn-Teller effect of Mn 3+ in the electrolyte, thereby enhancing structural stability.Benefiting from the synergistic effect of the two doped ions, the ion diffusion rate and conductivity of MnO are remarkably enhanced, thus exhibiting excellent electrochemical performance (Figure 7i,j).Unlike single-ion doping, multi-ion doping realizes the in situ bonding of manganese through the close arrangement of different heteroatoms, leading to the formation of robust manganese ion bindings within the crystal cell.Recently, Wang's group [161] prepared Co, Fe, Ni, Cu, and Cr co-doped MnO cathode materials (co-doped MnO) by a high-entropy-doping strategy.The molar contents of the five heteroelements is similar, and they all have the same molar ratio with Mn ions (Mn:X = 28.3:1).The interactions between the metal elements in the co-doped MnO promote a denser overlap of the electron cloud between Mn 2+ and O 2− , which greatly increases the binding energy of the MnO bond.In addition, a large number of oxygen defects introduced by Co, Fe, Ni, Cu, and Cr doping can accelerate the ion transport in the cathode material and enhance the reaction kinetics.Finally, this codoped high-entropy MnO exhibits excellent long-term cycle stability and rate performance (Figure 7k).
In summary, to address these issues (fewer active sites, poor electronic conductivity, and poor cycling performance) with MnO cathode materials, the prevailing strategies include co-doping to enhance intrinsic conductivity and high-entropy doping to bolster structural stability.Through doping engineering, a protective layer is introduced on the surface of MnO, which activates the inert phase, accelerates diffusion kinetics, boosts electronic conductivity, and mitigates manganese dissolution, thereby improving electrochemical performance.Additionally, doping engineering can introduce vacancies or defects to enhance the diffusion performance of Zn 2+ within the batteries.

Mn 2 O 3
Although Mn 2 O 3 has the superiority of high energy density and low production cost, it has the worst electrostatic instability compared with other crystalline phases of Mn x O y materials because the outermost 3d 4 electron configuration of trivalent manganese ions is more prone to electron transfer.However, this electrostatic instability leads to the reduction or oxidation of Mn 2 O 3 during the electrode reaction, thus destroying its chemical morphology and structure.To improve the electrostatic stability of Mn 2 O 3 , Zhang et al. [162] designed an oxygen-deficient Mn 2 O 3 cathode by doping with positive monovalent Cu ions (Figure 8a).They confirmed the presence of oxygen defects within the material using electron paramagnetic resonance spectroscopy (Figure 8b).These oxygen defects are instrumental in modifying the internal electric field of the material by compensating for the non-zero dipole moment, which in turn significantly enhances the material's electrostatic stability.Furthermore, the Cu-doped Mn 2 O 3 electrode demonstrates a substantial diffusion coefficient and commendable rate performance, ranging from 1 × 10 −6 to 1 × 10 −8 , coupled with a high degree of reversible cycling stability.At the same time, the construction of stronger ionic bonds by metal ion doping is also one of the effective methods to increase the stability of materials.Baeck et al. [54] successfully synthesized Ni-doped Mn 2 O 3 microspheres with excellent electrochemical properties through co-precipitation and subsequent heat treatment (Figure 8c).On the other hand, the introduction of Ni makes a large number of Ni-O-Mn interfaces appear in Mn 2 O 3 , in which the electronic structure of Ni-doped Mn 2 O 3 is well designed by effectively optimizing the adsorption energy of the intermediate.To confirm this, the XPS spectra of O 1s for Mn 2 O 3 and Ni-doped Mn 2 O 3 are examined and shown in Figure 8d.In order to eliminate the influence of surface contamination caused by carbon and oxygen pollutants in the atmosphere, Ar + ion beam sputtering was employed prior to the XPS test [163].The O 1s spectrum of Ni-doped Mn 2 O 3 can be divided into three peaks located at 529.4 eV, 530.9 eV, and 532.2 eV; the binding energy is different from the O adsorbed on the surface of the solid material (531.5 eV), so the three peaks are attributed to the metal-oxygen bond (O1), the O atom (O2) in the hydroxyl group, and the surface O defect site (O3), respectively [164].Compared to pure Mn 2 O 3 , the O 1s binding energy of Ni-doped Mn 2 O 3 is negatively shifted by 0.75 eV.This change is mainly due to the doping of Ni into Mn 2 O 3 , which enhances the ionic bond in Mn 2 O 3 to a certain extent, thereby enhancing the stability of the material.On the one hand, its excellent performance is due to the fact that the hierarchical and rough surface structure provides a larger active surface area and abundant active sites (Figure 8d), thereby achieving efficient mass transfer.In addition, Huang et al. [28] also found that the doping of the Ni element can effectively alleviate the dissolution of Mn 3+ in Mn 2 O 3 .As shown in Figure 8e, the incorporation of Ni 2+ increases the conductivity of Mn 2 O 3 due to the slight differences around the Fermi level.Furthermore, the presence of Ni 2+ facilitates electron rearrangement, which enhances the overall conductivity and ultimately improves the reaction kinetics and the electrochemical performance of Ni-Mn 2 O 3 .The intercalation of Ni 2+ into the crystal lattice of Mn 2 O 3 reduces its overall formation energy, thereby effectively enhancing the stability of the material and mitigating the dissolution of Mn.Consequently, the resulting NM cathode exhibits a higher specific capacity and a longer life (Figure 8f).Doping engineering can also increase the distribution of active sites in Mn2O3 materials or enhance the reaction kinetics to optimize the performance of the materials.Javanbakht's group [165] synthesized Ni-doped ZnMn2O4/Mn2O3 nanocomposites via pulse potential electrodeposition which were subsequently used as cathode materials for AZIBs.By analyzing the binding energy of the surface elements of the Ni-doped ZnMn2O4/Mn2O3 nanocomposites (Figure 8g), it can be seen that the characteristic peaks of Mn2O3 gradually shift with increasing Ni content.These changes are primarily attributed to the incorporation of Ni 2+ , which realizes the effective regulation of Mn 3+ and Mn 4+ concentrations (the concentration of Mn 3+ decreases and that of Mn 4+ increases).In addition, the incorporation of Ni 2+ also reduces the potential gap and improves the reversible insertion/extraction of Zn 2+ in the Ni-doped ZnMn2O4/Mn2O3.The Ni-doped ZnMn2O4/Mn2O3 nanocomposites still exhibit a discharge capacity of 114.67 m Ah g −1 after a long-term cycle stability test (at 2 A g −1 after 3000 cycles), which is much higher than that of the undoped nanocomposites.Davarani et al. [167] proposed a strategy to prepare Cr-doped Mn2O3 with cauliflowerlike nanostructures through constant-current cathodic electrodeposition.In this process, a Mn 2+ nitrate solution containing a small amount of dichromate was used as the raw material.During the synthesis process, the dispersed Cr ions in the solution played a certain role in inducing the preferential formation of MnO2 and then reacted with excess Mn 2+ to Doping engineering can also increase the distribution of active sites in Mn 2 O 3 materials or enhance the reaction kinetics to optimize the performance of the materials.Javanbakht's group [165] synthesized Ni-doped ZnMn 2 O 4 /Mn 2 O 3 nanocomposites via pulse potential electrodeposition which were subsequently used as cathode materials for AZIBs.By analyzing the binding energy of the surface elements of the Ni-doped ZnMn 2 O 4 /Mn 2 O 3 nanocomposites (Figure 8g), it can be seen that the characteristic peaks of Mn 2 O 3 gradually shift with increasing Ni content.These changes are primarily attributed to the incorporation of Ni 2+ , which realizes the effective regulation of Mn 3+ and Mn 4+ concentrations (the concentration of Mn 3+ decreases and that of Mn 4+ increases).In addition, the incorporation of Ni 2+ also reduces the potential gap and improves the reversible insertion/extraction of Zn 2+ in the Ni-doped ZnMn 2 O 4 /Mn 2 O 3 .The Ni-doped ZnMn 2 O 4 /Mn 2 O 3 nanocomposites still exhibit a discharge capacity of 114.67 m Ah g −1 after a long-term cycle stability test (at 2 A g −1 after 3000 cycles), which is much higher than that of the undoped nanocomposites.Davarani et al. [167] proposed a strategy to prepare Cr-doped Mn 2 O 3 with cauliflower-like nanostructures through constant-current cathodic electrodeposition.In this process, a Mn 2+ nitrate solution containing a small amount of dichromate was used as the raw material.During the synthesis process, the dispersed Cr ions in the solution played a certain role in inducing the preferential formation of MnO 2 and then reacted with excess Mn 2+ to form Mn 2 O 3 nanostructures.The introduction of Cr reduces the crystallinity and improves the morphology of Mn 2 O 3 products (Figure 8i) and finally shows superior performance compared to undoped manganese oxide materials.Ravi et al. [166] have developed selfassembled, three-dimensional, mesoporous, original α-Mn 2 O 3 microspheres, as well as neodymium (Nd)-doped variants, using a simple hydrothermal method.With 5% Nd doping, the Nd-Mn 2 O 3 exhibits a uniform morphological structure and an increased number of oxygen vacancies.These characteristics not only make the material distribute more electrochemical active sites but also shorten the diffusion distance of ions in the Mn 2 O 3 cathode material.As a result, the Mn 2 O 3 electrode demonstrates outstanding electrochemical activity, abundant ion mobility, a high specific capacity, and long cycle stability.

Mn 3 O 4
As a typical spinel metal oxide, Mn 3 O 4 is considered to be one of the cathode materials with great research significance for AZIBs due to its unique electronic structure, mixedvalence Mn 2+ / 3+ center, and unique three-dimensional pore structure [168,169].However, the rapid capacity fade and poor rate performance hinder its commercial application.It is generally known that improving the diffusion kinetics of materials during charge and discharge is crucial to optimize the rate performance of electrode materials.Shi et al. [169] synthesized mesoporous Al 0.35 Mn 2.52 O 4 with an enhanced specific surface area through a selective leaching process that targets the removal of aluminum (Al).As shown in Figure 9a-c, the spinel structure of Mn 3 O 4 is endowed with a multitude of defects by removing about 30% of Al ions.Characterization studies reveal that Zn 2+ has a faster diffusion rate in Al 0.35 Mn 2.52 O 4 with rich Mn vacancies.Concurrently, the absence of a significant electrostatic barrier, coupled with the heightened mobility of Zn 2+ , results in accelerated electrode kinetics.Furthermore, since H + tends to adsorb on the oxygen bridge site during the migration process and is also electrostatically repelled by the adjacent Mn in Mn 3 O 4 , the vacancy defect is also beneficial to reduce the diffusion barrier of H + .Lin et al. [52] synthesized Zn-doped Mn 3 O 4 and γ-MnO 2 nanocomposites (ZnMM-NSs) using an electrochemical deposition method.This process was conducted directly on the surface of nickel foam that had been modified with silver nanoparticles and carbon nanotubes, resulting in a vertically oriented three-dimensional porous nanosheet framework.It was observed that the doping of zinc ions creates an expedited path for both electron and ion diffusion.Compared with the undoped MnO 2 -NSs, the ZnMM-NSs electrode exhibited a larger Warburg slope at low frequencies (Figure 9d), indicating that it has faster diffusion kinetics.
It is worth noting that the enhancement of the intrinsic electronic/ionic conductivity of the material is very important for the optimization of the rate performance of the Mn 3 O 4 materials.Fortunately, doping engineering has been proved to be a meaningful way to improve the electronic/ionic conductivity of Mn 3 O 4 materials.Wang et al. [170] have reported on a multivalent cobalt-doped Mn 3 O 4 with high capacity and reversibility and have investigated the roles of cobalt ions with different valences.Among them, Co 2+ serves as a 'structural pillar' between the layers of intermediates (δ-MnO 2 ) of the cycle, while Co 4+ within the layer enhances the conductivity of Mn 4+ and helps to maintain a high specific capacity.Most notably, the introduction of Co 2+ and Co 3+ into the Mn 3 O 4 structure can effectively alleviate the Jahn-Teller effect of Mn 3+ during the cycling process and significantly guarantee the stability of the material structure (Figure 9e).The resulting Co-Mn 3 O 4 cathode still maintains a substantial discharge specific capacity of 292.6 mAh g −1 after 250 cycles at 200 mA g −1 , with a commendable capacity retention rate of 90% (Figure 9f).Kong et al. [171] developed Cu-doped Mn 3 O 4 as a cathode material for AZIBs.Due to the strong affinity, Cu 2+ partially substitutes for Mn 3+ within the manganese oxide lattice, culminating in the formation of a porous micro/nanostructure consisting of numerous irregular nanoparticles.As shown in Figure 9g, the conductivity and Zn 2+ diffusivity of the Cu-Mn 3 O 4 electrode is significantly enhanced by the Cu 2+ doping.The Cu-Mn 3 O 4 cathode achieves a discharge capacity of 250 mAh g −1 under 100 mA g −1 , surpassing that of the pure Mn 3 O 4 electrode (150 mAh g −1 ) (Figure 9h).In addition, the doping of other metal elements can also enhance the conductivity of the material by changing the element arrangement of the contact surface between the material and the electrolyte.For instance, Li et al. [172] synthesized cobalt-doped manganese oxide nanoparticles.Structural and electrochemical performance characterization demonstrated that Co doping enhanced the conductivity of [MnO 6 ] octahedra and facilitated the electron transport of Co-Mn 3 O 4 during both charging and discharging processes.Additionally, Co doping enhanced the diffusion of Zn 2+ on the surface of ZnMn 2 O 4 at the AC anode.
Doping engineering can also enhance the chemical activity of Mn 3 O 4 materials by adding more electrochemically active sites.Based on the study of electrodynamics, Nam et al. [173] discovered that Ni-doped Mn 3 O 4 with a doping level of 5% also exhibits enhanced electrochemical activity.This is mainly attributed to the distortion of the crystal structure of Mn 3 O 4 nanoparticles induced by the Ni doping.Such lattice distortion results in localized strain, which in turn manipulates the electronic structure (Figure 9i) and potentially increases the number of the electrochemical active sites.Zhang's group [174] uniformly dispersed the Fe element in ultrathin Mn 3 O 4 nanosheets.They discovered that Fe doping not only increases the distribution of electrochemical active sites but also confers excellent electrochemical activity to Fe-Mn 3 O 4 by adjusting the d-band center of Mn 3 O 4 and modifying the adsorption energy of oxygen-containing intermediates.On the other hand, the introduction of heteroatoms can induce the controllable evolution of the morphology and structure of the material, which in turn affects the content of electrochemical active sites.Yeenduguli et al. [175] prepared Cu-doped Mn 3 O 4 thin films by using the spray pyrolysis technique and conducted a detailed study of their structure and electrochemical properties.The addition of Cu not only changed the surface morphology and roughness but also significantly affected the overall morphology of Mn 3 O 4 .Furthermore, atomic force microscopy results revealed that when the Cu content reached 10 at%, the surface of the film became smooth, but the roughness paradoxically increased.This modification also led to an increased distribution of electrochemical active sites.Analysis of electrochemical impedance spectroscopy data revealed that the Cu-doped Mn 3 O 4 film can significantly reduce the electron transfer impedance of the film (Figure 9j).[173] discovered that Ni-doped Mn3O4 with a doping level of 5% also exhibits enhanced electrochemical activity.This is mainly attributed to the distortion of the crystal structure of Mn3O4 nanoparticles induced by the Ni doping.Such lattice distortion results in localized strain, which in turn manipulates the electronic structure (Figure 9i) and potentially increases the number of the electrochemical active sites.Zhang's group [174] uniformly dispersed the Fe element in ultrathin Mn3O4 nanosheets.They discovered that Fe doping not only increases the distribution of electrochemical active sites but also confers excellent electrochemical activity to Fe-Mn3O4 by adjusting the d-band center of Mn3O4 and modifying the adsorption energy of oxygen-containing intermediates.On the other hand, the introduction of heteroatoms can induce the controllable evolution of the morphology and structure of the material, which in turn affects the content of electrochemical active sites.Yeenduguli et al. [175] prepared Cu-doped Mn3O4 thin films by using the spray pyrolysis technique and conducted a detailed study of their structure and electrochemical properties.The addition of Cu not only changed the surface morphology and roughness but also significantly affected the overall morphology of Mn3O4.Furthermore, atomic force microscopy results revealed that when the Cu content reached 10 at%, the surface of the film became smooth, but the roughness paradoxically increased.This modification also led to an increased distribution of electrochemical active sites.Analysis of electrochemical impedance spectroscopy data revealed that the Cu-doped Mn3O4 film can significantly reduce the electron transfer impedance of the film (Figure 9j).

Conclusions and Perspective
This review focuses on doped Mn x O y cathodes in AZIBs.First, the structural characteristics of Mn x O y with different oxidation states and crystal phases, the Zn 2+ storage mechanisms of Mn x O y -based AZIBs, and the problems and optimization strategies of doped Mn x O y cathodes are briefly introduced.Then, the electrochemical properties of doped MnO, MnO 2 (α-, δ-, β-, ε-, γ-MnO 2 ), Mn 2 O 3 , and Mn 3 O cathodes and the corresponding performance improvement mechanisms are summarized and analyzed.Specifically, doping engineering serves the following modification functions: (i) the phase transition and volume change in the cathodes can be alleviated, ensuring their structural stability throughout the charge/discharge cycles; (ii) defects can be introduced into the structure, thereby increasing the number of active sites for ion or proton storage; and (iii) the improvement in the transfer rate of ions and electrons and the weakening of the electrostatic repulsion between Zn 2+ and MnO 2 resulting from the lattice expansion and charge redistribution is beneficial for the insertion/de-insertion of Zn 2+ .Finally, this review outlines future research directions of Mn x O y cathodes and AZIBs.

Study of Energy Storage Mechanisms
So far, representative storage mechanisms for Mn x O y cathodes mainly include the Zn 2+ intercalation/de-intercalation reaction, the Zn 2+ and H + co-intercalation/de-intercalation reaction, the chemical conversion reaction, dissolution/deposition, and hybrid reaction mechanisms.However, the energy storage mechanism of AZIBs is related to the composition, crystal structure, electrode morphology, electrolyte composition and concentration, and charging/discharging cycle times.An exact, reliable, and widely accepted mechanism of Mn x O y -based AZIBs still needs to be investigated.In situ characterization methods, including Raman diffraction, X-ray absorption diffraction, scanning and transmission electron microscopy, and electrochemical quartz crystal microbalance, enable the on-line monitoring of the phase and structural transformation of Mn x O y cathodes during the charging/discharging process.DFT calculations offer insights into potential reactions at the atomic level.In addition, the high-throughput method involves the use of an automated operating system to perform the experimental procedure and the use of a sensitive and fast test instrument to collect experimental data.Therefore, the strategy of integrating high-throughput in situ characterization techniques with high-throughput DFT calculations can not only help to accurately and comprehensively understand the reaction mechanism of Mn x O y cathodes but can also help to guide the design of suitable Mn x O y cathodes to improve the performance of AZIBs.

Construction of Nanostructured Mn x O y
Nanostructures generally possess a significant specific surface area, high porosity, and high penetrability.As a result, they can mitigate the structural collapse induced by the volumetric swelling of the cathode in the process of electrochemical reaction, shorten the transport pathway of Zn 2+ and electrons, and facilitate the insertion and extraction of Zn 2+ ions.Nanostructures are classified into one-dimensional, two-dimensional, and three-dimensional structures.A one-dimensional structure with a micron size in the radial direction serves as an effective channel for current collection.In contrast, the ultrathin thickness and ultra-large exposed area of a two-dimensional structure can facilitate the charge transfer, shorten the ion transport path, and provide more reactive sites.The excellent volume density and rich pores of a three-dimensional structure can provide abundant ion adsorption sites, sufficient volume change buffering areas, and high electrolyte permeability, effectively avoiding self-aggregation and the side reactions of cathodes.

Optimization of Doping Engineering of Mn x O y
Currently, the doping engineering of Mn x O y is mainly focused on either metal cation or non-metal anion doping.Anion doping refers to the replacement of oxygen metal elements of low electronegativity, accompanied by the generation of lattice vacancies, while cation doping involves the replacement of manganese with metal elements that can expand the lattice spacing, alleviate the crystal stress, modify the electronic property, and promote the insertion of Zn 2+ .Therefore, it is reasonable to expect that the simultaneous incorporation of metal cations and non-metal anions into Mn x O y could yield remarkable synergistic effects.In addition, there is still a lack of research on the precise control of doping concentration and sites.Next, it is of great importance to explore the intrinsic relationship between the type, concentration, and insertion site of doping elements and electrode kinetics in order to prepare high-performance doped Mn x O y cathodes and enhance the electrochemical characteristic of AZIBs.

Practical Challenges and Limitations of Doping Mn x O y for AZIBs
Despite that many achievements have been made in doping Mn x O y for AZIBs in previous studies, there are still two challenges that need to be overcome to facilitate the large-scale and practical development of doping Mn x O y for AZIBs.The first is to develop feasible and inexpensive methods to prepare doped Mn x O y materials.Although many methods (e.g., hydrothermal method, co-precipitation) have successfully prepared doped Mn x O y materials and displayed excellent electrochemical performance, most of these reported methods are complex and expensive for large-scale production.Thus, developing a feasible method with precise control of the doping site could greatly accelerate the commercialization of AZIBs.The second is to increase the areal capacity of cathode materials.Recently reported doped Mn x O y cathodes only demonstrated an areal capacity of 0.1-0.2mAh cm −2 due to the relatively low mass loading, which is far below the commercial standard (>2 mAh cm −2 ).Therefore, mass loadings higher than 10 mg cm −2 are urgently needed for the investigation of practical AZIBs.

Application of Doped Mn x O y -Based ZIBs in Flexible Storage Field
The instant development of flexible storage and the market-oriented utilization of portable electronic installations have promoted the development of flexible ZIBs with low cost and excellent bending rate tensile strength and environmental friendliness.On the one hand, the poor conductivity and lower specific capacity of Mn x O y cathodes hinder their further development in flexible ZIBs.Therefore, it is urgent to modify Mn x O y in order to boost the electrochemical characteristic.Additionally, aqueous batteries are unsuitable for flexible energy storage due to the evaporation and leakage of the aqueous electrolyte during the redox cycle.Therefore, the development of solid or gel electrolytes with good ductility, a high mechanical strength, and a wide operating temperature range and voltage window is of great significance for the commercialization of flexible ZIBs.

Figure 4 .
Figure 4. Overview of doping engineering for performance improvement in manganese-based metal oxides.(a) Enhancing intrinsic electron/ion conductivity.(b) Increasing electrochemical active sites.(c) Promoting diffusion kinetics.(d) Maintaining structural stability.

Figure 4 .
Figure 4. Overview of doping engineering for performance improvement in manganese-based metal oxides.(a) Enhancing intrinsic electron/ion conductivity.(b) Increasing electrochemical active sites.(c) Promoting diffusion kinetics.(d) Maintaining structural stability.

Materials 2024 ,
17, x FOR PEER REVIEW 24 of 33 can also enhance the conductivity of the material by changing the element arrangement of the contact surface between the material and the electrolyte.For instance, Li et al. [172] synthesized cobalt-doped manganese oxide nanoparticles.Structural and electrochemical performance characterization demonstrated that Co doping enhanced the conductivity of [MnO6] octahedra and facilitated the electron transport of Co-Mn3O4 during both charging and discharging processes.Additionally, Co doping enhanced the diffusion of Zn 2+ on the surface of ZnMn2O4 at the AC anode.Doping engineering can also enhance the chemical activity of Mn3O4 materials by adding more electrochemically active sites.Based on the study of electrodynamics, Nam et al.